Oral administration of doxycycline allows tight control of transgene expression: a key step towards gene therapy of retinal diseases.

Gene transfer of neurotrophic or antiangiogenic factors has been shown to improve photoreceptor survival in retinal degenerative disorders (that is retinitis pigmentosa) and to prevent neovascularization in retinal vascular diseases (that is age-related macular degeneration, diabetic retinopathy). Expression of such neurotrophic or antiangiogenic factors after gene transfer requires the use of a regulatory system to control transgene expression to avoid unwanted side effects in cases of overexpression. In a previous study, we demonstrated that rAAV-mediated gene transfer of the tetracycline-regulatable (tetR) system allows transgene regulation in the retina of nonhuman primates after intravenous administration of doxycycline (Dox). The purpose of this study was to evaluate oral administration of Dox to control transgene expression in the retina, since the pharmacokinetics after oral administration of the inducer drug represent a key factor when considering advancing to clinical trials. We report on the outcome of this evaluation and demonstrate that oral administration of Dox at a dose that is clinically used in humans (5 mg kg(-1) per day) is capable to continuously induce transgene expression in all macaques tested for 6 months. Moreover, control of transgene expression persists up to 4 years post-subretinal injection, with maximal induced levels of transgene product remaining stable over time.

Restoration of vision in RPE65-deficient Briard dogs using an AAV serotype 4 vector that specifically targets the retinal pigmented epithelium.

Previous studies have tested gene replacement therapy in RPE65-deficient dogs using recombinant adeno-associated virus 2/2 (rAAV2/2), -2/1 or -2/5 mediated delivery of the RPE65 gene. They all documented restoration of dark- and light-adapted electroretinography responses and improved psychophysical outcomes. Use of a specific RPE65 promoter and a rAAV vector that targets transgene expression specifically to the RPE may, however, provide a safer setting for the long-term therapeutic expression of RPE65. Subretinal injection of rAAV2 pseudotyped with serotype 4 (rAAV2/4) specifically targets the RPE. The purpose of our study was to evaluate a rAAV2/4 vector carrying a human RPE65cDNA driven by a human RPE65 promoter, for the ability to restore vision in RPE65-/- purebred Briard dogs and to assess the safety of gene transfer with respect to retinal morphology and function. rAAV2/4 and rAAV2/2 vectors containing similar human RPE65 promoter and cDNA cassettes were generated and administered subretinally in eight affected dogs, ages 8-30 months (n = 6 with rAAV2/4, n = 2 with rAAV2/2). Although fluorescein angiography and optical coherence tomography examinations displayed retinal abnormalities in treated retinas, electrophysiological analysis demonstrated that restoration of rod and cone photoreceptor function started as soon as 15 days post-injection, reaching maximal function at 3 months post-injection, and remaining stable thereafter in all animals treated at 8-11 months of age. As assessed by the ability of these animals to avoid obstacles in both dim and normal light, functional vision was restored in the treated eye, whereas the untreated contralateral eye served as an internal control. The dog treated at a later age (30 months) did not recover retinal function or vision, suggesting that there might be a therapeutic window for the successful treatment of RPE65-/- dogs by gene replacement therapy.